Authors:

Chad Meyer(Los Alamos National Laboratory)

James Quirk(Los Alamos National Laboratory)

Mark Short(Los Alamos National Laboratory)

Carlos Chqiuete(Los Alamos National Laboratory)

Programmed-burn methods are a class of models used
to propagate a detonation wave, without the high resolution cost
associated with a direct numerical simulation. They separate the detonation evolution calculation into two components: timing and energy release. The timing component is usually calculated with a Detonation Shock Dynamics model, a surface evolution representation that relates the normal velocity of the surface $(D_{n})$ to its local curvature. The energy release component must appropriately capture the degree of energy change associated with chemical reaction while simultaneously remaining synchronized with the timing component. The Pseudo-Reaction-Zone (PRZ) model is a reactive burn like energy release model, converting reactants into products, but with a conversion rate that is a function of the DSD surface $D_{n}$ field. As such, it requires the DSD calculation produce smooth $D_{n}$ fields, a challenge in complex geometries. We describe a new body-fitted approach to the Detonation Shock Dynamics calculation which produces the required smooth $D_{n}$ fields, and a method for calibrating the PRZ model such that the rate of energy release remains as synced as possible with the timing component. We show results for slab, rate-stick and arc geometries.

To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2016.DFD.G26.2